Abstract
Single-crystal SiC is a typical third-generation semiconductor power-device material because of its excellent electronic and thermal properties. An ultrasmooth surface with atomic surface roughness that is scratch free and subsurface damage (SSD) free is indispensable before its application. As the last process to reduce the surface roughness and remove surface defects, precision polishing of single-crystal SiC is essential. In this paper, precision polishing technologies for 4H-SiC and 6H-SiC, which are the most commonly used polytypes of single-crystal SiC, such as chemical mechanical polishing (CMP), photocatalytic chemical mechanical polishing (PCMP), plasma-assisted polishing (PAP), electrochemical mechanical polishing (ECMP), and catalyst-referred etching (CARE), were reviewed and compared with emphasis on the experimental setup, polishing mechanism, material removal rate (MRR), and surface roughness. An atomically smooth surface without SSD can be obtained by CMP, PCMP, PAP, and CARE for single-crystal SiC. However, their MRRs are meager, and the waste treatment after CMP is difficult and expensive. Moreover, PAP’s operation is poor due to the complex polishing system, plasma generation, and irradiation devices. A high MRR can be achieved by ECMP. In addition, it is an environmentally friendly precision polishing process for single-crystal SiC since the neutral salt solution is generally used as the electrolyte in ECMP. However, the formation of the egglike protrusions at the oxide/SiC interface during anodic oxidation would lead to a bigger surface roughness after ECMP than that after PAP is processed. The HF solution used in CARE was toxic, and Pt was particularly expensive. Ultrasonic vibration-assisted single-crystal SiC polishing and electrolyte plasma polishing (EPP) were discussed; furthermore, the research direction of further improving the surface quality and MRR of single-crystal SiC was prospected.
Highlights
Single-crystal SiC is widely considered a typical third-generation semiconductor material for the fabrication of power devices working with high voltage and high frequency and under high-temperature conditions owing to its many excellent electrical and chemical properties, such as wide energy band gap, excellent thermal conductivity, high breakdown electric field, and good chemical stability
The surface roughness of the SiC substrate seriously affects their performance; the electric breakdown field intensity and charge to breakdown have been confirmed to increase with decreasing surface roughness, which has been confirmed to increase the transconductance of a MOS transistor [8]
The results showed that if the SiC oxidation rate was higher than the SiO2 layer removal rate, a residual oxidation layer was left on the SiC surface, which resulted in many scratches
Summary
Single-crystal SiC is widely considered a typical third-generation semiconductor material for the fabrication of power devices working with high voltage and high frequency and under high-temperature conditions owing to its many excellent electrical and chemical properties, such as wide energy band gap, excellent thermal conductivity, high breakdown electric field, and good chemical stability. Single-crystal SiC precision polishing technologies have been widely investigated in recent years, such as chemical mechanical polishing (CMP) [10,11], plasma-assisted polishing (PAP) [12,13], photocatalytic chemical mechanical polishing (PCMP) [14], electrochemical mechanical polishing (ECMP) [15,16], catalyst-referred etching (CARE) [17,18], and anodic etching [19] These studies mainly focused on improving the material removal rate (MRR) and surface quality of single-crystal SiC. Ultrasonic vibration-assisted polishing and electrolyte plasma polishing (EPP) were discussed as well, and the research direction for the surface quality and MRR’s further improvement was prospected
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